Acid Buffering One of the major ways in which large changes in H+ concentration are prevented is by buffering. The body buffers which are primarily weak acids, are able to take up or release H+ so that changes in the free H+ concentration are minimized. Buffers are located in the extracellular fluid (ECF), intracellular fluid and bone. Extracellular Buffers The most important buffer in the ECF and the body is HCO3- (bicarbonate) which combines with excess H+ ions to form carbonic acid. Take for instance an acid load of H2SO4 produced via metabolism of methionine: H2SO4 + 2NaHCO3 NA2SO4 + 2H2CO3 2CO2 + 2H2O + NA2SO4.

Note in this buffering reaction that bicarbonate reacts with a strong acid to form a weaker acid(H2CO3) which then dissociates into CO2 and H2O. The CO2 produced here does not reform H2CO3 because it is then excreted by the lungs. Note that HCO3- is used up in this reaction. So that pH is not affected, the HCO3- used up in this process must be regenerated and the NA2SO4 must be excreted by the kidneys. The CO2/HCO3- buffer system is considered very effective because of the vast quantity of bicarbonate in the body and the ability to excrete the CO2 formed via ventilation. Other less important buffers in the ECF are plasma proteins and inorganic phosphates. Intracellular Buffers The primary intracellular buffers are proteins, organic and inorganic phosphates and in the RBC, hemoglobin (HB-). Whereas buffering by plasma HCO3- occur almost immediately, approximately 24 hours is required for buffering by cell buffers due to slow cell entry. Hemoglobin is a very important buffer in RBCs, particularly in the role of carbonic acid buffering. It should also be noted that transcellular uptake of hydrogen ions by cells result in the passage of Na+ and K+ ions out of cells to maintain electroneutrality. This process can substantially affect potassium balance as will be discussed later.

Bone Bone represents an important site of buffering acid load. An acid load, is associated with the uptake of excess H+ ions by bone which occurs in exchange for surface Na+ and K+ and by the dissolution of bone mineral, resulting in the release of buffer compounds, such as NaHCO3, CaHCO3, and CaHPO4.

It has been estimated that at least 40% of the buffering of an acute acid load takes place in bone. Chronic acidosis can have very adverse effects on bone mineralization due to this process and can result in bone diseases such as rickets, osteomalacia and osteopenia.

Daily Acid Load The daily acid load is constituted by ones diet, and is comprised primarily of foods containing acid, and the production of acid as a result of metabolism. The intake of alkali containing foods and the production of alkali as a result of metabolism offsets the daily acid load but the net effect is daily addition of acid to the body that must be buffered and excreted to maintain acid base balance. There are 2 types of acids that can potentially contribute to the daily acid load; carbonic or volatile acid (H2CO3) and noncarbonic or nonvolatile acids. Carbonic acids Metabolism of fats and carbohydrates result in the production of 15-20 mol of CO2 per day. Before elimination by the lungs, most of the CO2 is taken up by red blood cells, reacting with H2O to form carbonic acid as shown below: CO2 + H2O H2CO3(CA) H+ + HCO3-

where (CA) is the very important enzyme carbonic anhydrase. Intracellularly, carbonic acid dissociates to form hydrogen and bicarbonate ions. The latter is pumped out of the cell into plasma. At the alveoli, bicarbonate ions re-enter the RBC and the above equation is driven to the left, re-producing CO2 which is then eliminated by the lung. Under normal circumstances, CO2 produced via metabolism is primarily eliminated via alveoli ventilation. Any increases in CO2 production is matched by an increase in alveolar ventilation leading to a stable PCO2 level.

Nonvolatile Acids Metabolism of amino acids, producing HCL and H 2SO4 Intake of acid containing foods-sulphates, phosphates Daily loss of alkali in feces (minimal unless diarrhea)

Volatile Acids (H 2CO3) Metabolism of fats and carbohydrates producing CO 2

Noncarbonic acids Noncarbonic acids on the other hand are primarily derived from the metabolism of proteins and dietary intake of foods containing sulphates (H2SO4) and phosphates (H2PO4 ) and are primarily responsible for the daily acid load that requires excretion by the kidneys. A normal diet results in the generation of 50 -100 meq of H+ per day. Most of this comes from the metabolism of sulphur containing amino acids such as cysteine and methionine which yield sulphuric acid and from metabolism of lysine, arginine and histidine which yield hydrochloric acid. Ingestion of alkali containing foods (e.g. citrate), and metabolism of amino acids such as aspartate and glutamate that lead to alkali production offset the daily acid load but the net effect is daily acid addition.

Renal Acid Excretion The process of renal acid excretion is complex. In order to conceptualize this process, lets consider the follow equation: HCl + NaHCO3 NaCl + H2CO3 CO2 + H2O + NACl.

The above equation represents the process of buffering of the daily nonvolatile acid load. Buffering minimizes the effect that strong acids such as HCl would have on the pH. Nonetheless the pH will be affected if the bicarbonate lost in this process is not regenerated, because as we will learn; loss of bicarbonate from the ECF lowers the extracellular pH, leading to acidosis. One way to regenerate the lost bicarbonate would be for the kidney to reverse the above equation, and excrete HCl in the urine as free H+ ions. Unfortunately this would require a urine pH of 1.0, an impossible task since the minimum attainable urine pH is 4.0 to 4.5. In order to maintain acid base balance, the kidney must accomplish two tasks: 1) Reabsorption of all filtered bicarbonate 2) Excrete the daily acid load The kidney achieves these three tasks effectively via the processes of hydrogen secretion, bicarbonate reabsorption and excretion of hydrogen ions with urinary buffers( titratable acids and ammonium) . Hydrogen Ion Secretion The kidney is responsible for excreting the nonvolatile acid load, which as previously mentioned, is equivalent to about 50-100meq/L of hydrogen ions per day. Hydrogen ions are buffered in the blood and are not filtered by the kidney as free ions. Hydrogen ions are instead excreted in the urine via the process of hydrogen ion secretion . In the tubular fluid, the secreted hydrogen ions combine with urinary buffers to be excreted as titratable acids and ammonium or combine with filtered bicarbonate leading to bicarbonate reabsorption. Bicarbonate Reabsorption y The kidney filters approximately 4320 meq/day of HCO3- (24 meq/L 180L/day). Under normal circumstances, the kidney is able to completely reabsorb all the filtered bicarbonate. This is vitally important, since any loss of bicarbonate in the urine would disturb acid base balance. y The process of bicarbonate reabsorption occur predominantly in the proximal tubule (about 90%). The rest occur in the thick ascending limb and in the collecting tubule. All involve hydrogen ion secretion as shown in the diagram below. To completely reabsorb bicarbonate,the kidney must secrete 4320 meq/day of hydrogen ions in addition to the amount required to exrete the daily acid load.

y The primary step in proximal hydrogen secretion is the secretion of H+ by the Na+ - H+ antiporter in the luminal membrane. Hydrogen ions are generated by the intracellular breakdown of H20 to OH- and H+. y Hydrogen ions secreted combine with filtered HCO3- ions to form carbonic acid and then CO2 + H2O, which are then passively reabsorbed. y Technically, HCO3- ions reabsorbed in this process are not the same as the ones filtered. Note that a new HCO3- ion is generated from the intracellular breakdown of H20 to OH- and H+ and subsequent reaction of OH- with CO2 to form HCO3- . This new bicarbonate then crosses the basolateral membrane via a Na+ - 3HCO3- cotransporter. y The net effect is one mol of bicarbonate ion returned to systemic circulation for every H+ ion that is secreted and reabsorption of virtually all filtered bicarbonate. y Similar processes occur in the thick ascending loop of Henle and intercalating cells of the collecting duct. In contrast to the proximal tubule, hydrogen ion secretion in the collecting tubule is mediated by a H+ ATPase pump in the luminal membrane and a Cl-HCO3exchanger in the basolateral membrane as shown in the diagram above. The H+ ATPase pump is influenced by aldosterone, which stimulates increased H+ secretion. Hydrogen ion secretion in the collecting tubule is the process primarily responsible for acidi fication of the urine, particularly during states of acidosis. The urine pH may fall as low as 4.0. y Proximal reabsorption of bicarbonate can be affected by many factors, in particular, potassium balance, volume status and renin/angiotensin levels . Therefore these factors can have very significant effects on acid base balance. Their specific effects will be discussed later.

Urinary Buffering The role of urinary buffering serves two purposes; to a) excrete the daily acid load and b) regenerate bicarbonate lost during extracellular buffering. It is a process whereby seceted hydrogen ions are buffered in the urine by combining with weak acids (titratable acidity) or with NH3 (ammonia) to be excreted. It is a necessary process because the kidney cannot easily excrete free hydrogen ions.

Titratable Acidity y The major titratable acid buffer is HPO 4 . Other less important buffers are creatinine and uric acid. In DKA, ketoanions also serve as a source of titratable acids. Below is a diagram outlining this process.2-

y Excretion of titratable acids is dependent on the quantity of phosphate filtered and excreted by the kidneys, which is dependent on one's diet,and also PTH levels. As such, the excretion of titratable acids is not regulated by acid base balance and cannot be easily increased to excrete the daily acid load. Ammonium production can however be regulated to respond to acid base status, as will be discussed next. Ammonium Excretion With increased acid load, there is increased hydrogen ion secretion, causing the urine pH to fall below 5.5. At this point, virtually all the urinary phosphate exist as H2PO4- and further buffering cannot occur unless there is an increase in urinary phosphate excretion. As mentioned previously, phosphate excretion is mainly dependent on dietary phosphate intake and PTH levels and is not regulated in response to the need to maintain acid base balance. Without further urinary buffering, adequate acid excretion cannot take place. The major adaptation to an increased acid load is increased ammonium production and excretion. The ability to excrete H+ ions as ammonium adds an important degree of flexibility to renal acid base regulation, because the rate of NH4+ production and excretion can be regulated in response to the acid base requirements of the body. Also of importance is the role of ammonium production in the furth er generation of bicarbonate ions. The process of ammonium excretion takes place in 3 steps. y Ammonium Formation (ammoniagenesis) (proximal tubule) y Ammonium Reabsorption (Medullary Recycling)(thick ascending loop) y Ammonium Trapping (collecting tubule)

Ammoniagenesis The process of ammoniagenesis occurs within proximal tubular cells. Glutamine made in the liver, is received from peritubular capillaries and is metabolized into alpha-keto glutarate and NH4+, in a reaction that involves the enzyme glutaminase.

The ammonium is secreted into the tubular lumen by substituting for H+ on the Na+ - H+ exchanger. In the tubular fluid, NH4+ circulates partly in equilibrium with NH3. The alpha-ketoglutarate is metabolized further into two HCO3- ions, which then leave the cell and enter systemic circulation by crossing the basolateral membrane. Please note that the generation of new HCO3 - ions is probably the most important feature of this process. This will be explained next. Below is a diagram outlining Ammonium formation .

The Role of Ammonium Excretion What happens next to ammonium is somewhat complex. So before continuing , let us re-examine the rational behind ammonium excretion. Now remember; free hydrogen ions are not filtered by the kidney. Instead, they are secreted into the tublar fluid. Because free hydrogens cannot be excreted in the urine easily, there are excreted with weak acids such as H2PO4- which function as urinary buffers. Now in the presence of an increased acid load, the phospate ions are used up and the kidney then increases its production of ammonium . Notice that ammonium, not ammonia is produced in the proximal tubule. Therefore you might ask yourself, how does ammonium production increase hydrogen excretion if it cannot bind to hydrogen ions secreted in the proximal tubular lumen? The answer to this is somewhat controversial in the literature. Below is one school of thought that has gained popularity. As was mentioned previously, new bicarbonate ions are produced during ammoniagenesis. The generation of new bicarbonate ions conceptually is akin to inceased hydrogen excretion. Therefore the real function of ammoniagenesis is not as a urinary buffer of hydrogen ions as is commonly inaccurately described. The real function of ammoniagensis is to increase the generation of new bicarbonate ions. For simplicity, this rational will be the basis of the remaining discussion on ammonium excretion. Ammonium before it is excreted is first re-absorbed in the thick ascending limb, circulated in the medullary interstitium and then pumped back in the collected tubule as ammonia. In the collecting tubule, ammonia then takes up hydrogen ions secreted into the lumen by intercalated cells, to form ammonium.

Now the second question you might ask is why so many steps leading to the same result?

In order for ammoniagenesis to be effective in the generation of new HCO3 -, the NH4+ produced must be excreted in the urine . If NH4+ were to enter the circulation, it would end up in the liver where metabolism would lead to the formation of urea as showed in the following equation: NH4+ + 2 HCO3- => urea + CO2 + 3 H2O Notice that the formation of urea consumes 2 molecules of bicarbonate. Therefore, in essence, the bicarbonate generated in the proximal tubule would be negated or cancelled out, and ammoniagenesis would not increase net acid excretion. As mentioned previously, NH4+ secreted in the proximal tubule is in equilibrium with a small quantity of NH3. This NH3 is capable of diffusing out of the lumen into the peritubular capillaries. If this were allowed to continually happen, a large quantity of ammonium would be lost to the circulation and its metabolism in the liver would consume the HCO3- generated. This effect is minimized by having an acidic urine ph which keeps NH4+ in its protonated form. However, the urine does not become maximally acidified until the collecting tubule where secretion of hydrogen ions by intercalated cells significantly reduce the urine pH. Therefore the kidney prevents loss of ammonium by reabsorbing NH4+ in the thick ascending limb and pumping it into the collecting duct where the urine pH is very low, facilitating ammonia in its protonated form. This process is enhanced during periods of acidosis when hydrogen secretion by the intercalated cells is significantly increased. Medullary Recycling and Ammonium Trapping. After ammoniagenesis, ammonium is taken up into the medullary interstitium via a process called medullary recycling. It is then pumped back into the tubular fluid at the level of the collecting duct, where it undergoes what is called ammonium trapping after which it is excreted. Below is an outline of this process.

1. Ammonium is first reabsorbed at the level of the thick ascending limb by substituting for K+ on the Na+ -K+ -2Cl- carrier. 2. The less acidic tubular cell then causes NH4+ to dissociate into NH3 and H+. 3. The luminal membrane in the thick ascending limb is impermeable to NH3 and thus NH3 cannot diffuse back into the lumen. It instead diffuses out into the medullary interstitium into those compartments which have the lowest NH3 concentration, i.e. the S3 segment of the proximal tubule and the medullary interstitium of the collecting tubule.

4. At the S3 segment of the proximal tubule, NH3 re-enters the lumen where it is protonated back to NH4 and is again recycled back into the medullary interstitium via reabsorption at the thick ascending limb. This leads to a high concentration of NH3 in the medullary interstitium. 5. Because of the very low NH3 concentration in the collecting tubular fluid (as a result of removal in the loop of Henle), and a maximally acidic urine pH in the collecting duct that further reduces tubular NH3, there is a large gradient for NH3 secretion into the collecting tubular lumen. 6. In contrast to the thick ascending limb, the tubular lumen is permeable to NH3 but not to NH4. As a result, NH3 secretion into the collecting duct lumen leads to ammonium trapping as NH4+ formed from the very acidic urine is unable to diffuse back into the cell. 7. NH4 is then excreted in the urine, usually with a Cl- anion.

Note that this process is primarily dependent on acidification of the urine in the collecting tubule as a result of hydrogen secretion by intercalated cells. In states of acidosis, where hydrogen secretion is significantly increased in the collecting tubule, this process is greatly enhanced. In states of alkalosis, the process is appropriately hindered as a result of the alkalemic urine. Renal Acid Exretion; Take Home Points 1. The net quantity of H+ ions excreted in the urine is equal to the amount of H+ excreted as titratable acidity and NH4+ minus any H+ added to the body because of urinary HCO3- loss. Net acid excretion(NAE) = titratable acidity + NH 4 - urinary HCO 3 Note that normally there is no urinary HCO3- and therefore: + Net acid excretion(NAE) = titratable acidity + NH 4 2. Titratable acidity is dependent on the dietary intake of phosphate and cannot be regulated to increase acid excretion 3. The kidney 's main response to an increased acid load is to increase ammonium production and excretion 4. A very important feature of titrable acidity and ammonium excretion is the regeneration of bicarbonate ions. 5. The kidney must reabsorb all filtered HCO3- in order to maintain acid base balance. 6. Hydrogen ion secretion in the collecting tubule is very important in maximally acidifying the urine. 7. In states of acidosis, maximal acidification of the urine in the collecting tubule must occur for adequate ammonium excretion. 8. In states of acidosis, ammonium excretion is increased by increasing ammonium production and increased hydrogen ion secretion in the collecting duct. 9. Aldosterone stimulates secretion of hydrogen ion in the collecting duct . 10. Although the extracellular pH is the primary physiologic regulator of net acid excretion, in pathophysiologic states, the effective circulating volume, Aldosterone, and the plasma K+ concentration all can affect acid excretion, independent of the systemic pH.+ -

Pumonary Acid Excretion The main physiologic stimuli to respiration are an elevation in the PCO2 and a reduction in the PO2 (hypoxemia). The CO2 stimulus to ventilation occurs in the chemosensitive areas in the respiratory center in the brain stem, which responds to CO2 induced changes in the cerebral interstitial pH. This effect is important in removing the 15 mol of CO2 produced daily from metabolism of fats and carbohydrates, via alveolar ventilation. In acid base disorders, the initial rise or fall in alveolar ventilation is mediated primarily by the peripheral chemoreceptors in the carotid or aortic bodies, which immediately sense the change in pH. Changes in PCO2 are sensed via central chemoreceptors as CSF ph is altered. In general, PCO2 is regulated by alveolar ventilation. Hyperventilation (increase in alveolar ventilation) enhances CO2 excretion and lowers the PCO2 while hypoventilation (reduction in ventilation) reduces CO2 excretion and raises the PCO2. The effects of acid base balance on alveolar ventilation and vice versa will be discussed in more detail when specific acid base disorders are described.

ACID BASE ABNORMALITIES This teaching module will provide an overview of acid base abnormalities. Below is a list of topics that will be covered: y y y y y y Introduction to Acid Base Disturbances and Definitions Compensatory Responses Calculations: Anion Gap, Delta Ratio, Urine Anion Gap, Osmolar Gap Step by Step Approach to interpreting an arterial blood gas Physiologic Effects of Acid Base Disorders Etiology of Acid Base Disorders

If first time user of this tutorial, please click next to continue. Otherwise, you may click on topics in the submenu as you wish. Introduction to Acid Base Disorders In order to approach acid base disorders, consider the following equations: 1) Henderson Hasselbalch equation: pH = 6.1 + log [HCO3-]/ 0.03 PCO2 where 6.1 is the pKa (negative logarithm of the acid dissociation constant) for carbonic acid (H2CO3) and 0.03, the factor which relates PCO2 to the amount of CO2 dissolved in plasma. 2) Kassirer-Bleich equation: [H+] = 24 PCO2 / [HCO3-] pH 7.80 7.70 7.60 7.50 7.40 7.30 7.20 7.10 7.00 6.90 6.80 [H+], nanomol/L 16 20 26 32 40 50 63 80 100 125 160

Although cumbersome and somewhat difficult to use at the bedside, both equations represent a very important relationship. They predict that the ratio of dissolved CO2 to HCO3- , rather than their actual concentrations, determines hydrogen ion concentration and thus pH. A drop or rise in PCO2 will result in a drop or rise in [H+] respectively. [HCO3-] on the other hand is inversely related to H+ concentration whereby a drop in bicarbonate levels result in an increase in H+ concentration while a rise in bicarbonate levels result in a reduction in H+ concentration. This buffer system is of physiologic importance because both the pulmonary and renal mechanisms for regulating pH work by adjusting this ratio.

The PCO2 can be modified by changes in alveolar ventilation, while plasma [HCO3-] can be altered by regulating its generation and excretion by the kidneys. Definitions An acid base disorder is a change in the normal value of extracellular pH that may result when renal or respiratory function is abnormal or when an acid or base load overwhelms excretory capacity. Normal acid base values pH 7.35- 7.45 7.40 PCO2 36-44 40 HCO322-26 24

Range: Optimal value

Acid base status is defined in terms of the plasma pH. Acidemia - decrease in the blood pH below normal range of 7.35 -7.45 Alkalemia - Elevation in blood pH above the normal range of 7.35 7.45 Clinical disturbances of acid base metabolism classically are defined in terms of the HCO3- /CO2 buffer system. Acidosis process that increases [H+] by increasing PCO2 or by reducing [HCO3-] Alkalosis process that reduces [H+] by reducing PCO2 or by increasing [HCO3-]

It is important to note that though acidosis and alkalosis usually leads to acidemia and alkalemia respectively, the exception occurs when there is a mixed acid base disorder. In that situation, multiple acid base processes coexisting may lead to a normal pH or a mixed picture. This will be discussed in more detail later. Since PCO2 is regulated by respiration, abnormalities that primarily alter the PCO2 are referred to as respiratory acidosis (high PCO2) and respiratory alkalosis (low PCO2). In contrast, [HCO3-] is regulated primarily by renal processes. Abnormalities that primarily alter the [HCO3-] are referred to as metabolic acidosis (low [HCO3-]) and metabolic alkalosis (high [HCO3]). Simple acid base disorders : Disorders that are either metabolic or respiratory. Mixed acid base disoders: More than one acid base disturbance present. pH may be normal or abnormal. Compensatory Responses Acid Base disoders are associated with defense mechanisms referred to as compensatory responses that function to reduce the effects of the particular disorder on the pH. They do not restore the pH back to a normal value. This can only be done with correction of the underlying cause. In each of these disorders, compensatory renal or respiratory responses act to minimize the change in H+ concentration by minimizing the alteration in the PCO2 /[HCO3-] ratio. This teaching module will examine the compensatory responses associated with each acid base disorder.

Compensatory Responses: Metabolic Acidosis Metabolic Acidosis is an acid base disturbance characterized by a reduction in bicarbonate ions leading to an elevation in the PCO2/HCO3- ratio and thus an elevation in hydrogen ion concentration according to the following equation: [H+] = 24 (PCO2 / [HCO3-]) In metabolic acidosis, this reduction in bicarbonate ions may result from increased extracellular buffering of an increased acid load or less commonly; loss of bicarbonate ions in the urine. Remember that, HCO3- is the main buffer of nonvolatile or noncarbonic acids in the body and therefore in the presence of excess acid, its concentration will decrease. The body responds to metabolic acidosis by trying to restore the PCO2 / [HCO3-] ratio. This is done by reducing the PCO2. The reduction in PCO2 is accomplished by increasing alveolar ventilation. The drop in arterial pH stimulates both the central and peripheral chemoreceptors controlling respiration, resulting in an increase in alveolar ventilation. The inccrease in ventilation is characterized more by an increase in tidal volume than by an increase in respiratory rate, and may if the acidemia is severe, reach a maximum of 30L/min (nl = 5-6 L/min). In its most pronounced clinical manifiestation, the increase in ventilation is referred to as Kussmaul Respiration. In general, respiratory compensation results in a 1.2 mmHg reduction in PCO2 for every 1.0 meq/L reduction in the plasma HCO3 - concentration down to a minimum PCO2 of 10 to 15mmHg. For example, if an acid load lowers the plasma HCO3- concentration to 9 meq/L, then: Degree of HCO3- reduction is 24 (optimal value) 9 = 15. Therefore, PCO2 reduction should be 15 1.2 = 18. Then PCO2 measured should be 40 (optimal value) 18 = 22mmHg. Winter's Formula To estimate the expected PCO2 range based on respiratory compensation, one can also use the Winter's Formula which predicts: PCO2 = (1.5 [HCO3-]) + 8 2 Therefore in the above example, the PCO2 according to Winter's should be (1.5 9) + 8 2 = 20-24 Another useful tool in estimating the PCO2 in metabolic acidosis is the recognition that the pCO2 is always approximately equal to the last 2 digits of the pH. Compensatory Responses: Respiratory Acidosis Respiratory Acidosis is an acid base disturbance characterized by an elevation in the partial pressure of dissolved CO2 leading to an elevation in the PCO2/[HCO3-] ratio which subsequently increases the hydrogen ion concentration according to the following equation: [H+] = 24 PCO2 / [HCO3-] In Respiratory Acidosis, the elevation in PCO2 result from a reduction in alveolar ventilation. Elevation in PCO2 is never due to an increase in CO2 production. In response to the increase in [H+] and reduction of the pH, the body responds by trying to increase the plasma [HCO3-] to match the increase in PCO2 and thus maintain the PCO2/HCO3- ratio. This is

accomplished via two mechanisms; a) rapid cell buffering and b) an increase in net acid excretion. Because these mechanisms occur at different moments in time, acute respiratory acidosis can be distinguished from chronic respiratory acidosis. Acute Respiratory Acidosis Cell buffering occur within minutes after the onset of respiratory acidosis. The elevation in CO2 levels lead to an increase in carbonic or volatile acid in the plasma. Unlike nonvolatile acids, carbonic acid (H2CO3 ) cannot be buffered by HCO3- in the extracellular fluid. Therefore, in contrast to metabolic acidosis, bicarbonate levels do not fall in respiratory acidosis.. In this setting, carbonic acid (H2CO3 ) can only be buffered by the limited intracellular buffers (primarily hemoglobin and proteins). H2CO3 + HbHHb + HCO3As shown above, each buffering reaction produces HCO3-, which leads to an increase in plasma [HCO3-]. Due to this process, acutely, there is an increase in the plasma [HCO 3-], averaging 1 meq/L for every 10 mmHg rise in the PCO2. Chronic Respiratory Acidosis In chronic respiratory acidosis, the persistent elevation in PCO2 stimulates increased excretion of titratable acid and ammonium, resulting in the addition of new HCO3- to the extracellular fluid. This process is complete after 3-5 days resulting in a new steady state in which there is approximately a 3.5 meq/L increase in the plasma HCO3- concentration for every 10 mmHg increase in the PCO2. To put into perspective the impact of cell buffering vs renal adaptation on protecting the pH in respiratory acidosis, consider the following examples: If the PCO2 is acutely increased to 80 mmHg, there will be approximately a 4meq/L elevation in the plasma [HCO3-] to 28 meq/L and a potentially serious reduction in extracellular pH to 7.17. Change in PCO2 = 80- 40 = 40. Therefore elevation in [HCO3-] = 40/10 1 = 4 According to the Henderson-Hasselbach equation, pH = 6.1 + log[HCO3-]/0.03 PCO2 Hence pH = 6.1 + log (28/ 0.0380) = 7.17. In another example: If the PCO2 were chronically increased to 80 mmHg, the plasma [HCO3-] should rise by 14 ([(80-40)/10] 3.5) to a new concentration of 38 meq/L (24+14) The pH in this situation would be: pH = 6.1 + log (38/ 0.0380) = 7.30

Thus renal compensation offers more significant pH protection in the setting of chronic respiratory acidosis in contrast to intracellular buffering in the acute situation.

Chronic respiratory acidosis is commonly caused by COPD. These patients can tolerate a PCO2 of up to 90-110 mmHg and not have a severe reduction in pH due to renal compensation . Compensatory Responses: Metabolic Alkalosis Metabolic alkalosis is an acid base disorder characterized by an elevation in [HCO3-] above the normal range, which leads to a reduction in the PCO2/[HCO3-] ratio and subsequently a reduction in hydrogen ion concentration according to the following equation: [H+] = 24 (PCO2 / [HCO3-]) This elevation in bicarbonate ions is due to an addition in alkali to the body which then cannot be excreted by the kidney. Metabolic alkalosis is always associated with renal impairment of some kind because the kidney has a vast capacity in excreting excess alkali. Please note, loss of acid from the body as occurs in vomiting induced metabolic alkalosis is equivalent to adding alkali to the body. In response to the reduction in [H+] and elevation in pH, the body responds by trying to increase the PCO2 to match the increase in [HCO3-] and thus maintain the PCO2/[HCO3] ratio. Elevation in PCO2 is accomplished by lowering alveolar ventilation. The development of alkalemia is sensed by central and peripheral chemoreceptors, resulting in a reduction in the rate of ventilation and a reduction in tidal volume and thus an elevation in the pCO2. This happens fairly quickly following the onset of metabolic alkalosis. On average the pCO2 rises 0.7 mmHg for every 1.0 meq/L increment in the plasma [HCO3 -]. For example, if an alkali load raises the the plasma HCO3- concentration to 34 meq/L, then: Degree of HCO3- elevation is 34 24 (optimal value)= 10. Therefore, PCO2 elevation should be 0.7 10 = 7. Then PCO2 measured should be 40 (optimal value) +7 = 47mmHg. Compensatory Responses: Respiratory Alkalosis Respiratory alkalosis is caused by an elevation in the frequency of alveolar ventilation and more importantly tidal volume that result in an increase in minute ventilation. The increase in ventilation leads to the excretion of CO2 at a rate greater than that of cellular CO2 production. This leads to a net reduction in PCO2 and subsequently to a reduction in the PCO2 / [HCO3-] ratio which reduces the hydrogen ion concentration (and increases the pH) according to the following equation: [H+] = 24 PCO2 / [HCO 3-] In response to the decrease in [H+] and elevation in pH, the body responds by trying to reduce the plasma [HCO3 -] to match the reduction in PCO2 and thus maintain the ratio. There are two mechanisms responsible for this compensation to respiratory alkalosis; 1) rapid cell buffering and 2) a decrease in net renal acid excretion. As in respiratory acidosis, these responses occur in different moments of time, distinguishing acute respiratory alkalosis from chronic respiratory alkalosis.

Acute Respiratory Alkalosis About 10 minutes after the onset of respiratory alkalosis, hydrogen ions move from the cells into the extracellular fluid, where they combine with [HCO3- to form carbonic acid in the following reaction: H+ + HCO3H2CO3 (CA)

The hydrogen ions are primarily derived from intracellular buffers such as hemoglobin, protein and phosphates. The reaction with bicarbonate ions in this reaction leads to a mild reduction in plasma [HCO3-]. In acute respiratory alkalosis, as a result of cell buffering, for every 10 mmHg decrease in the PCO2, there is a 2meq/L decrease in the plasma HCO3- concentration. Please note that the cellular buffering does not offer adequate protection against respiratory alkalosis. For example: If the PCO2, were reduced to 20 mmHg, the change in PCO2 would be 20 (40-20) and therefore the fall in plasma [HCO3-] would be 4 meq/L (20/10 2). The new plasma [HCO3-] would be 20 meq/L (24-4). The pH in this circumstance would be: pH = 6.1 + log (20/ 0.0320) = 7.63 Had no cell buffering occurred, then the pH would be pH = 6.1 + log (24/ 0.0320) = 7.70 As you can see, really not much of a change. Chronic Respiratory Alkalosis If respiratory alkalosis persist for longer than 2- 6 hours, the kidney will respond by lowering hydrogen secretion, excretion of titratable acids, ammonium production and ammonium excretion. There will also be an increase in the amount of HCO3- excreted due to decreased reabsorption of filtered HCO 3- . Completion of this process occurs after 2-3 days after which a new steady state is achieved. Renal compensation result in a 4 meq/L reduction in plasma [HCO 3-] for every 10 mmHg reduction in PCO2 . In comparison, to acute respiratory alkalosis, this compensation offers a much better protection of the arterial pH. To put this into perspective, consider the same 20 mmHg fall in PCO2 as before in the acute scenario. Now, due to renal compensation, the plasma [HCO3 -] falls by 8 meq/L to 16 meq/L. The pH now in the chronic situation would be : pH = 6.1 + log (16/ 0.0320) = 7.53. Calculations There are various calculations that are commonly used diagnostically in interpreting acid base disorders and distinguishing between different causes of acid base disorders. Calculating the anion gap is an approach that must be taken in all cases of metabolic acidosis. Other calculations such as osmolar gap and urine anion gap, are used when clinically, the cause of an acid base disorder is in doubt. This teaching module will discuss the various diagnostic calculations that can be useful in interpreting acid base disorders. Emphasis will be placed on the underlying rational behind each formula to increase comprehension and deduction and minimize memorization. Topics to be covered are: y y y y Anion Gap Delta Ratio Urine Anion Gap Osmolar Gap

Compensatory Responses: summary and take home points 1. Compensatory responses never return the ph to normal or overshoot. 2. The basis of compensatory responses is to maintain the PCO2/[HCO3-] ratio. 3. Therefore, the direction of the compensatory response is always the same as that of the initial change. 4. Compensatory response to respiratory disorders is two-fold; a fast response due to cell buffering and a significantly slower response due to renal adaptation. 5. Compensatory response to metabolic disorders involves only an alteration in alveolar ventilation. 6. Metabolic responses cannot be defined as acute or chronic in terms of respiratory compensation because the extent of compensation is the same in each case. Below is table summarizing compensatory responses and their mechanisms. Initial Compensatory chemical response change

Primary disorder

Compensatory Mechanism

Expected level of compensation PCO2 = (1.5 [HCO3-]) + 8 2

Metabolic Acidosis

HCO3-

PCO2

Hyperventilation

PCO2 = 1.2 [HCO3-] PCO2 = last 2 digits of pH PCO2 = (0.9 [HCO3-]) + 16 2 PCO2 = 0.7 [HCO3-]

HCO3-

PCO2

Hypoventilation

Respiratory Acidosis Acute Chronic Respiratory Alkalosis Acute Chronic

PCO2

HCO3Intracellular Buffering (hemoglobin, intracellular proteins) Generation of new HCO3- due to the increased excretion of ammonium. [HCO3-] = 1 mEq/L for every 10 mm Hg PCO2 [HCO3-] = 3.5 mEq/L for every 10 mm Hg PCO2

PCO2

HCO3Intracellular Buffering Decreased reabsorption of HCO3-, decreased excretion of ammonium [HCO3-] = 2 mEq/L for every 10 mm Hg PCO2 [HCO3-] =4 mEq/L for every 10 mm Hg PCO2

Also: In acute respiratory acidosis, pH = 0.008 PCO2 In chronic respiratory acidosis, pH = 0.003 PCO2. PREVIOUS NEXT > Anion Gap When acid is added to the body, the [H+] increases and the [HCO3-] decreases. In addition, the concentration of the anion, which is associated with the acid, increases. This change in the anion concentration provides a convenient way to analyze and help determine the cause of a metabolic acidosis by calculating what is termed the anion gap. The anion gap is estimated by subtracting the sum of Cl- and HCO3- concentrations from the plasma Na concentration.

Metabolic Alkalosis

Na + Unmeasured cations = Cl- + HCO3- + Unmeasured anions Anion gap = [Na] ([Cl-] + [HCO3-]) The major unmeasured cations are calcium, magnesium, gamma globulins and potassium. The major unmeasured anions are negatively charged plasma proteins (albumin), sulphate, phosphates, lactate and other organic anions. The anion gap is defined as the quantity of anions not balanced by cations. This is usually equal to 12 4 meq/L and is usually due to the negatively charged plasma proteins as the charges of the other unmeasured cations and anions tend to balance out. If the anion of the acid added to plasma is Cl- , the anion gap will be normal (i.e., the decrease in [HCO3-] is matched by an increase in [Cl-]). For example: HCl + NaHCO3 NaCl + H2CO3 CO2 + H2O In this setting, there is a meq. for meq. replacement of extracellular HCO3- by Cl- ; thus, there is no change in the anion gap, since the sum of Cl-] + [HCO3-] remains constant. This disorder is called a hyperchloremic acidosis, because of the associated increase in the Cl- concentration. GI or renal loss of HCO3- produces the same effect as adding HCl as the kidney in its effort to preserve the ECV will retain NaCl leading to a net exchange of lost HCO3- for Cl-. In contrast, if the anion of the acid is not Cl- (e.g. lactate, -hydroxybutyrate), the anion gap will increase (i.e. the decrease in [HCO3-] is not matched by an increase in the [Cl-] but rather by an increase in the [unmeasured anion]: HA + NaHCO3 NaA + H2CO3 CO2 + H2O, where A- is the unmeasured anion. Causes of elevated Anion gap acidosis is best remembered by the mnemonic KULT or the popular MUDPILES M = Methanol U = Uremia D = DKA (also AKA and starvation) P = Paraldehyde I = INH L = Lactic acidosis E = Ethylene Glycol S = Salycilate K = Ketoacidosis (DKA,alcoholic ketoacidosis, starvation) U = Uremia (Renal Failure) L =Lactic acidosis T = Toxins (Ethylene glycol, methanol, paraldehyde, salicylate)

Because, negatively charged plasma proteins account for the normal a nion gap, the normal values should be adjusted downward for patients with hypoalbuminemia. The approximate correction is a reduction in the normal anion gap of 2.5 meq/l for every 1g/dl decline in the plasma albumin concentration (normal value = 4 g/dl). See practice case 8 for an example.

The Delta Ratio (/) The delta ratio is sometimes used in the assessment of elevated anion gap metabolic acidosis to determine if a mixed acid base disorder is present. Delta ratio = Anion gap/ [HCO3 -] or anion gap/ Delta Delta = Measured anion gap Normal anion gap Delta del Normal [HCO3-] Measured [HCO3-] Delta Delta = (AG 12) Delta delaaa(24 - [HCO3-]) In order to understand this, let us re-examine the concept of the anion gap. If one molecule of metabolic acid (HA) is added to the ECF and dissociates, the one H+ released will react with one molecule of HCO3- to produce CO2 and H2O. This is the process of buffering. The net effect will be an increase in unmeasured anions by the o ne acid anion A- (ie anion gap increases by one) and a decrease in the bicarbonate by one meq. Now, if all the acid dissociated in the ECF and all the buffering was by bicarbonate, then the increase in the AG should be equal to the decrease in bicarbonate so the ratio between these two changes (which we call the delta ratio) should be equal to one. As described previously, more than 50% of excess acid is buffered intracellularly and by bone, not by HCO3- . In contrast, most of the excess anions remain in the ECF, because anions cannot easily cross the lipid bilayer of the cell membrane. As a result, the elevation in the anion gap usually exceeds the fall in the plasma [HCO3- ]. In lactic acidosis, for example, the / ratio averages 1.6:1. On the other hand, although the same principle applies to ketoacidosis, the ratio is usually close to 1:1 in this disorder because the loss of ketoacids anions (ketones) lowers the anion gap and tends to balance the effect of intracellular buffering. Anion loss in the urine is much less prominent in lactic acidosis because the associated state of marked tissue hypoperfusion usually results in little or no urine output. A delta-delta value below 1:1 indicates a greater fall in [HCO3-] than one would expect given the increase in the anion gap. This can be explained by a mixed metabolic acidosis, i.e a combined elevated anion gap acidosis and a normal anion gap acidosis, as might occur when lactic acidosis is superimposed on severe diarrhea. In this situation, the additional fall in HCO3- is due to further buffering of an acid that does not contribute to the anion gap. (i.e addition of HCl to the body as a result of diarrhea) A value above 2:1 indicates a lesser fall in [HCO3-] than one would expect given the change in the anion gap. This can be explained by another process that increases the [HCO3-],i.e. a concurrent metabolic alkalosis. Another situation to consider is a pre-existing high HCO3- level as would be seen in chronic respiratory acidosis.Delta ratio < 0.4 2

See case 3 and 7 for examples. Urine Anion Gap The three main causes of normal anion gap acidosis are: y Loss of HCO3- from Gastrointestinal tract (diarrhea) y Loss of HCO3- from the Kidneys (RTAs) y Administration of acid Distinguishing between the above 3 groups of causes is usually clinically obvious, but occasionally it may be useful to have an extra aid to help in deciding between a loss of base via the kidneys or the bowel. Calculation of the urine anion gap may be helpful diagnostically in these cases. The measured cations and anions in the urine are Na+, K+, and Cl- ; thus the urine anion gap is equal to: Urine anion gap = [Na+] + [K+] - [Cl-] Urine anion gap = unmeasured anions unmeasured cations In normal subjects, the urine anion gap is usually near zero or is positive. In metabolic acidosis, the excretion of the NH4+ (which is excreted with Cl- ) should increase markedly if renal acidification is intact. Because of the rise in urinary Cl- , the urine anion gap which is also called the urinary net charge, becomes negative, ranging from -20 to more than -50 meq/L. The negative value occurs because the Cl- concentration now exceeds the sum total of Na+ and K+. In contrast, if there is an impairment in kidney function resulting in an inability to increase ammonium excretion (i.e. Renal Tubular Acidosis), then Cl- ions will not be increased in the urine and the urine anion gap will not be affected and will be positive or zero. In a patient with a hyperchloremic metabolic acidosis: A negative UAG suggests GI loss of bicarbonate (eg diarrhea), a positive UAG suggests impaired renal acidification (ie renal tubular acidosis). As a memory aid, remember neGUTive - negative UAG in bowel causes. Remember that in most cases the diagnosis may be clinically obvious (severe diarrhea is hard to miss) and consideration of the urinary anion gap is not necessary. See case 5 for an example. Osmolar Gap The Osmolar Gap is another important diagnostic tool that can be used in differentiating the causes of elevated anion gap metabolic acidosis. The major osmotic particles in plasma are Na+ , Cl- , HCO3-, urea and glucose and as such, plasma osmolarity can be estimated as follows: Plasma osmolarity = 2(Na) + glucose/18 + BUN/2.8 Note that because Cl- and HCO3- are always bound to Na, their contributions to osmolarity are estimated by doubling the Na concentration. Plasma osmolality (Posm) can also be measured directly by freezing point depression. The osmolar gap is the difference between the calculated serum osmolarity and the measured serum osmolarity. Osmolar Gap = Measured Posm Calculated Posm The normal osmolar gap is 10-15 mmol/L H20 .The osmolar gap is increased in the presence of low molecular weight substances that are not included in the formula for calculating plasma osmolarity.

Common substances that increase the osmolar gap are ethanol, ethylene glycol, methanol, acetone, isopropyl ethanol and propylene glycol.

In a patient suspected of poisoning, a high osmolar gap (particularly if 25) with an otherwise unexplained high anion gap metabolic acidosis is suggestive of either methanol or ethylene glycol intoxication. One must correlate an elevated osmolar gap with other clinical findings because it is a relatively nonspecific finding that is also commonly seen in alcoholic and diabetic ketoacidosis, lactic acidosis and in chronic renal failure. Elevation in the osmolar gap in these disease states is thought to be due in part to elevations of endogenous glycerol, acetone, acetone metabolites, and in the case of renal failure, retention of unidentified small solutes. Stepwise approach to interpreting the arterial blood gas. 1. H&P. The most clinical useful information comes from the clinical description of the patient by the history and physical examination. The H&P usually gives an idea of what acid base disorder might be present even before collecting the ABG sample 2. Look at the pH. Is there an acid base disorder present? - If pH < 7.35, then acidemia - if pH > 7.45, then alkalemia - If pH within normal range, then acid base disorder not likely present. - pH may be normal in the presence of a mixed acid base disorder, particularly if other parameters of the ABG are abnormal. 3. Look at PCO2, HCO3-. What is the acid base process (alkalosis vs acidosis) leading to the abnormal pH? Are both values normal or abnormal? - In simple acid base disorders, both values are abnormal and direction of the abnormal change is the same for both parameters. - One abnormal value will be the initial change and the other will be the compensatory response. 3a. Distinguish the initial change from the compensatory response. - The initial change will be the abnormal value that correlates with the abnormal pH. - If Alkalosis, then PCO2 low or HCO3- high - If Acidosis, then PCO2 high or HCO3- low. Once the initial change is identified, then the other abnormal parameter is the compensatory response if the direction of the change is the same. If not, suspect a mixed disorder. 3b. Once the initial chemical change and the compensatory response is distinguished, then identify the specific disorder. See table below. - If PCO2 is the initial chemical change, then process is respiratory. - if HCO3- is the initial chemical change, then process is metabolic. Acid Base Disorder Respiratory Acidosis Respiratory Alkalosis Metabolic Acidosis Metabolic Alkalosis Initial Chemical Change PCO2 PCO2 HCO3HCO3Compensatory Response HCO3HCO3PCO2 PCO2

4. If respiratory process, is it acute or chronic? - An acute respiratory process will produce a compensatory response that is due primarily to rapid intracellular buffering.

- A chronic respiratory process will produce a more significant compensatory response that is due primarily to renal adaptation, which takes a longer time to develop. - To assess if acute or chronic, determine the extent of compensation. See table. 5. If metabolic acidosis, then look at the Anion Gap. - If elevated (> than 16), then acidosis due to KULT. (Ketoacidosis, Uremia, Lactic acidosis, Toxins). See table. - If anion gap is normal, then acidosis likely due to diarrhea, RTA. 6. If metabolic process, is degree of compensation adequate? - Calculate the estimated PCO2, this will help to determine if a seperate respiratory disorder is present. See table. 7. If anion gap is elevated, then calculate the Delta-Ratio (/) to assess for other simultaneous disorders. - / compares the change in the anion gap to the change in bicarbonate. - If ratio between 1 and 2, then pure elevated anion gap acidosis - If < 1, then there is a simultaneous normal anion gap acidosis present. - if > 2, then there is a simultaneous metabolic alkalosis present or a compensated chronic respiratory acidosis. 8. If normal anion gap and cause is unknown, then calculate the Urine Anion Gap (UAG). This will help to differentiate RTAs from other causes of non elevated anion gap acidosis. - In RTA, UAG is positive. - In diarrhea and other causes of metabolic acidosis, the UAG is negative. (neGUTive in diarrhea) Physiologic Effects of Acidosis Respiratory Effects y Hyperventilation ( Kussmaul respirations) y Shift of oxyhaemoglobin dissociation curve to the right y Decreases 2,3 DPG levels in red cells, which opposes the effect above. (shifts the ODC back to the left) This effect occurs after 6 hours of acidemia. Cardiovascular Effects y Depression of myocardial contractility (this effect predominates at pH < 7.2 ) y Sympathetic over-activity ( tachycardia, vasoconstriction, decreased arrhythmia threshold) y Resistance to the effects of catecholamines (occur when acidemia very severe) y Peripheral arteriolar vasodilatation y Venoconstriction of peripheral veins y Vasoconstriction of pulmonary arteries y Effects of hyperkalemia on heart Central Nervous System Effects y Cerebral vasodilation leads to an increase in cerebral blood flow and intracranial pressure (occur in acute respiratory acidosis) y Very high pCo2 levels will cause central depression Other Effects y Increased bone resorption (chronic metabolic acidosis only) y Shift of K+ out of cells causing hyperkalemia ( an effect seen particularly in metabolic acidosis and only when caused by non organic acids) y Increase in extracellular phosphate concentration

Physiologic Effects of Alkalosis Respiratory Effects y Shift of oxyhaemoglobin dissociation curve to the left (impaired unloading of oxygen y The above effect is however balanced by an increase in 2,3 DPG levels in RBCs. y Inhibition of respiratory drive via the central & peripheral chemoreceptors Cardiovascular Effects y Depression of myocardial contractility y Arrhythmias Central Nervous System Effects y Cerebral vasoconstriction leads to a decrease in cerebral blood flow ( result in confusion, muoclonus, asterixis, loss of consciousness and seizures ) Only seen in acute respiratory alkalosis. Effect last only about 6 hours. y Increased neuromuscular excitability ( resulting in paraesthesias such as circumoral tingling & numbness; carpopedal spasm) Seen particularly in acute respiratory alkalosis. Other Effects y Causes shift of hydrogen ions into cells, leading to hypokalemia.

Note: Most of the above effects are short lasting. Physiologic Effects of Alkalosis Respiratory Effects y Shift of oxyhaemoglobin dissociation curve to the left (impaired unloading of oxygen y The above effect is however balanced by an increase in 2,3 DPG levels in RBCs. y Inhibition of respiratory drive via the central & peripheral chemoreceptors Cardiovascular Effects y Depression of myocardial contractility y Arrhythmias Central Nervous System Effects y Cerebral vasoconstriction leads to a decrease in cerebral blood flow ( result in confusion, muoclonus, asterixis, loss of consciousness and seizures ) Only seen in acute respiratory alkalosis. Effect last only about 6 hours. y Increased neuromuscular excitability ( resulting in paraesthesias such as circumoral tingling & numbness; carpopedal spasm) Seen particularly in acute respiratory alkalosis. Other Effects y Causes shift of hydrogen ions into cells, leading to hypokalemia.

Note: Most of the above effects are short lasting.

Metabolic Acidosis A primary metabolic acidosis is characterized by low arterial pH (< 7.35), reduced plasma HCO3- concentration, and compensatory alveolar hyperventilation resulting in decreased PCO2. It can be induced by either increased endogenous acid production, increased exogenous acid administration, loss of HCO3-, or by decreased ability to excrete the normal dietary H+ load. Differential Diagnosis The differential diagnosis of metabolic acidosis is vast and is best approached if one breaks down the causes of metabolic acidosis into normal vs elevated anion gap metabolic acidosis. See below. Elevated Anion Gap (>16 meq) Increased Endogenous production: Normal Anion Gap (8-16 meq) Loss of Bicarbonate: Diarrhea Carbonic anhydrase inhibitors Type 2 RTA (proximal) Pancreatic ileostomy Pancreatic, biliary, intestinal fistula Exogenous Administration : ammonium chloride or HCL Decreased Renal Acid Excretion: Type 1(distal) ,4 RTA Renal Failure Miscellaneous: Hyperkalemia Recovery from DKA

Ketoacidosis (Alcohol, Starvation, DKA)

Lactic Acidosis

Uremia Intoxications: Methanol, Ethylene Glycol, Paraldehyde, Salicylates, INH Lactic Acidosis

A commonly encountered cause of elevated anion gap metabolic acidosis, particularly in the ICU is lactic acid. Lactic acidosis is characterized by a pH < 7.36 and lactate level > 5mmol/L Lactic acid is produced under normal aerobic states in cells of the brain, retina, and erythrocytes. Under normal circumstances, lactate is circulated to the liver, and to a lesser degree the kidney, where it is converted into glucose or CO2 and H2O. Lactate + 3O2 HCO3- + 2CO2 + 2H2O 2 Lactate + 2CO2 + 2H2O 2HCO3- + glucose. In hypoxic states (low O2 supply) such as in strenuous muscle activity (seizure) or in low tissue perfusion states from circulatory failure, lactic acid is also produced anaerobically during glycolysis. This occurs via the following reaction:

This conversion of pyruvate to lactate in anaerobic conditions is promoted by the accumulation of NADH and the depletion of NAD+ which is needed as an electron acceptor so that glycolysis can continue. The conversion to lactate results in the regeneration of NAD+ so that minimal amounts of ATP can be made indefinitely from glycolysis in states of very low tissue oxygenation. Lactate accumulation and lactic acidosis results because in states of low tissue perfusion such as shock, or in states of mitochondrion dysfunction, lactate cannot be recycled to the liver for conversion back to glucose or for further breakdown because both of these reactions as shown above require oxygen and both take place in the mitochondrion. There are primarily 2 types of lactic acidosis: Type A Due to tissue hypoperfusion and hypoxia Type B Not due to tissue hypoperfusion and hypoxia. Type A Lactic Acidosis Most cases of lactic acidosis are due to reduced oxygen delivery as a result of reduced tissue perfusion from shock or cardiopulmonary arrest. Other conditions such as acute pulmonary edema, can cause severe hypoxemia leading to reduced O2 delivery. Other causes are carbon monoxide poisoning and severe anemia. Other causes of type A lactic acidosis which may not necessarily involve generalized tissue hypoxia are severe seizure, severe exercize and hypothermic shivering. All of which result in localized skeletal muscle hypoxia leading to increased lactic acid production. The clinical signs usually indicate reduced tissue perfusion and include severe hypotension, tachypnea, oliguria or anuria, peripheral vasoconstriction and deteriorating mental status. Sepsis, particularly in critically ill patients is a very important cause of lactic acidosis and is often associated with fever (>38.5C) or hypothermia (35C). Kussmaul hyperventilation (deep sighing respiration) may be observed if the severity of the acidosis is sufficient to elicit a degree of respiratory compensation. Lactic acidosis is usually associated with laboratory abnormalities indicating organ failure or compromise such as abnormal liver function tests, elevated BUN and elevated creatinine. Lactate levels are usually greater than 5 meq/L. Upper limit of nl is 1.6 in plasma. Anion gap is classically elevated, > 16. Type B Lactic Acidosis Usually without clinically apparent tissue hypoxia and can be due to any number of conditions: y Underlying diseases: DM, uremia, liver disease, infections, malignancies y Drugs and toxins: ethanol, methanol, ethylene glycol, salicylates, metformin y Inborn errors of metabolism: pyruvate dehydrogenase deficiency, glycogen storage disease, pyruvate carboxylase deficiency, etc. y Other : D-Lactic acidosis (short bowel syndrome) *, idiopathic Typical picture includes acute onset after nausea and vomiting, altered state of consciousness and hyperventilation. Laboratory findings are variable depending on underlying cause. D-Lactic Acidosis* Easily missed diagnosis, because the isomer responsible for the acidosis is the D- isomer which is not detected by the standard assay for lactate. This unique form of lactic acidosis can occur in patients with jejunoilelal bypass, or less commonly, small bowel resection or other causes of the short bowel syndrome. In these settings, the glucose and starch are metabolized in the colon into D-lactic acid, which is then absorbed into the systemic circulation. The ensuing acidemia tends to persist, since D-lactate is not recognized by L-lactate dehydrogenase, the enzyme that catalyzes the conversion of the physiologically occurring L-lactate into pyruvate.

Two factors that tend to contribute to the accumulation of D-lactate systemically are 1) an overgrowth of gram positive an aerobes, such as lactobacilli that are most able to produce Dlactate and 2) increased delivery of glucose and starch to the colon in the presence of a shorter small bowel transit. Patients typically present with recurring episodes of metabolic acidosis, usually after a carbohydrate meal, and characteristic neurologic abnormalities including confusion, cerebella ataxia, slurred speech, and loss of memory. Criteria for D-lactic acidosis: y Presence of short bowel syndrome with an intact colon. y An acute episode of encephalopathic symptoms, such as confusion, slurred speech , ataxia, unsteady gait, abusive behavior and/or nystagmus y Metabolic acidosis with an increased anion gap y Normal L-lactate levels y Serum D-lactate levels > 3 mmom/L y Abnormal colonic flora, with a predominance of Gram positive anaerobic bacteria (Lactobacilli, which produce large amounts of lactic acid) Treatment for Lactic Acidosis Treatment of lactic acidosis requires identification of the primary illness and therapy directed toward correction of that disturbance. Restoration of tissue oxygen delivery through hemodynamic and/or respiratory support is the key therapeutic goal in type A lactic acidosis, which will reduce further lactate production and allow metabolism of excess lactate to HCO3- . Unlike other forms of metabolic acidosis, the use of sodium bicarbonate in lactic acidosis is controversial, particularly in patients with circulatory and respiratory failure. Proponents argue that raising the arterial pH may improve tissue perfusion, by reversing acidemia induced vasodilatation and impaired cardiac contractility, and may diminish the risk of serious arrhythmias. Others argue that the NaHCO3 administration may actually worsen acidosis, particularly in patients with respiratory compromise due to the generation of CO2 from the metabolism of NaHCO3. It is thought that this CO2 accumulates in tissues leading to worsening intracellular acidosis. The intracellular acidosis leads to reduced lactate utilization in hepatic cells and a decline in cardiac contractility leading to reduced cardiac output and paradoxically further promotion of lactic acid production . Others also argue that NaHCO3 administration carries with it a risk of volume overload and overshoot metabolic alkalosis after normal hemodynamic has been restored. Despite the controversy most physicians support administration of NaHCO3 for very severe acidemia and will give small amounts of NaHCO3 to maintain the arterial pH above 7.10, since a pH beyond this value will promote the development of arrhythmias and cardiac depression. Treatment for D-Lactic acidosis Spontaneous regeneration of HCO3- does not occur in D-lactic acidosis, since D-lactate cannot be metabolized. Therapy for D-lactic acidosis consists of sodium bicarbonate administration to correct the acidemia and oral antibiotics to decrease gram positive anaerobic colonic bacteria. A low carbohydrate diet is also helpful in the reducing carbohydrate delivery to the colon. Ketoacidosis Ketoacidosis is a common form of elevated anion gap metabolic acidosis seen in patients with insulin requiring diabetes mellitus, alcoholics and pts undergoing fasting or starvation and is due to the overproduction of ketone bodies (Ketosis) leading to accumulation of ketones in plasma (Ketonemia) and urine (Ketonuria). The basic mechanism for the development of Ketonemia is as the following. In starvation states where plasma glucose levels are low or in states of low plasma insulin where uptake of glucose by cells is diminished, fatty acids will be mobilized and transported to tissues (brain, skeletal muscle,

heart) for fatty acid oxidation and energy production. Fatty acids are also transported to the liver, where due to diminished citric cycle activity resulting from gluconeogenesis, acetyl CoA from fatty acid oxidation can not be oxidized and is instead converted to the generation of ketone bodies. These ketone bodies (acetoacetate and -hydroxybutyrate) serve as a source of fuel for other tissues, in particular, the brain. Ketonemia arises when this process is prolonged due to prolonged states of glucose unavailability, as the hepatic production of ketone bodies overwhelms the capacity of extrahepatic tissues to oxidize them. Accumulation and ionization of ketones in plasma result in the release of excess hydrogen ions which then lead to acidosis.

Diabetic Ketoacidosis (DKA) Uncontrolled type 1 diabetes mellitus is the most common cause of ketoacidosis. The lack of insulin contributes to this condition not only via decreased glucose uptake but also by promoting lipolysis (triglyceride breakdown) and fatty acid oxidation. It is a state that also includes an increase in counter-regulatory hormones (ie, glucagon, cortisol, growth hormone, epinephrine) which contribute to hyperglycemia by promoting further gluconeogenesis and to ketonemia by promoting acetyl COA migration into mitochondrion where they can be converted into ketones. Progressive rise of blood concentration of these acidic organic substances initially leads to a state of ketonemia. Natural body buffers can buffer ketonemia in its early stages. When the accumulated ketones exceed the body's capacity of extracting them, they overflow into urine (ie, ketonuria). If the situation is not treated promptly, more accumulation of organic acids leads to frank clinical metabolic acidosis (ie, ketoacidosis), with a drop in pH and bicarbonate serum levels. Hyperglycemia usually exceeds the renal threshold of glucose absorption and results in significant glycosuria. Consequently, water loss in the urine is increased (polyuria) due to osmotic diuresis induced by glycosuria. This incidence of increased water loss results in severe dehydration, thirst, tissue hypoperfusion, and, possibly, lactic acidosis. In addition, beta hydroxybutyrate induces nausea and vomiting that consequently aggravate fluid loss. Typical free water loss in DKA is approximately 6 liters or nearly 100 mL/kg of body weight. Hyperglycemia, osmotic diuresis, serum hyperosmolarity, and metabolic acidosis result in severe electrolyte disturbances. The most characteristic disturbance is total body potassium loss. Total body potassium loss is usually present despite normal or high serum potassium levels. Potassium levels may appear to be high due to the transcellular shift of potassium out of cells. This is not due to ketoacidosis directly but rather is due to insulin deficiency and hyperosmolality. A large part of the shifted extracellular potassium is lost in urine because of osmotic diuresis. Also, when ketoacids are excreted, they are usually excreted with Na or K in the urine, leading to further K loss. Vomiting may also contribute to potassium loss in these patients. Patients with initial hypokalemia are considered to have severe and serious total body potassium depletion . In addition, hyponatremia is usually present, and is usually due to the dilutional effect of hyperosmolality as water is shifted from intracellular to extracellular compartments. The direct effect of hyperosmolarity is often counteracted by the glucosuria -induced osmotic diuresis. The diuresis results in water loss in excess of sodium and potassium, which will tend to raise the plasma sodium concentration and plasma osmolality unless there is a comparable increase in water intake. As such, hyponatremia is usually mild. The combined effects of serum hyperosmolarity, dehydration, and acidosis result in increased osmolarity in brain cells that may clinically manifest as an alteration in the level of consciousness. History y 25% of patients present with DKA as first presentation of their diabetes mellitus. y Usually triggered by illness: UTI, infection, stress (medical or emotional), MI y May also be due to poor compliance, or missed injections due to vomiting

y Insidious increased thirst (ie, polydipsia) and urination (ie, polyuria) are the most common early symptoms of DKA. y Nausea and vomiting may occur associated with diffuse abdominal pain y Lethargy, somnolence, confusion may develop y Dyspnea Signs y Signs of dehydration - Weak and rapid pulse, dry tongue and skin, hypotension, and increased capillary refill time y Oral odor - Characteristic fruity odor (from acetone, a product of acetoacetate metabolism y Signs of acidosis - Deep sighing breathing, abdominal tenderness, and disturbance of consciousness y Body temperature may be within the reference range or low, even in the presence of intercurrent infection. Laboratory y Urine dipstick highly positive for glucose, ketones (dipstick detect acetoacetate but not beta-hydroxybutyrate which is the predominant ketone, therefore test not always positive initially for ketones) y Serum ketones present y ABG : low bicarbonate, low PCO2, pH < 7.35 y Anion gap > 16 y Serum K normal, high or low. y Serum Na low phos low. y Serum phosphate: usually phosphate depleted due to urine losses but are normal or high by labs due to transcellular shift out of cells in the setting of acidosis and insulin deficiency. After treatment with Insulin, phosphate levels usually low y Serum glucose usually > 300 mg/dl but below 800mg/dl (unlike NKH, where > 1000 mg/dl) y Leukocytosis, even in the absence of infection y Bun/Cr high due to prerenal azotemia Treatment The major goals of treatment are 1) rapid fluid volume expansion, 2) correction of hyperglycemia and hyperketonemia, 3) prevention of hypokalemia during treatment, and 4) identification and treatment for any associated bacterial infection 1. Fluids: IVF, in adults, rapid infusion of 1L of 0.9% NS (e.g. over 30 min), repeat bolus as necessary to prevent shock. When BP is stable and urine output adequate, can switch to 0.45% NS at a slower rate. This is done to replace the free water loss induced by the osmotic diuresis. 2. Insulin infusion : 10-20 unit bolus (0.15 u/kg), then 5-7 units/hr (0.1 unit/kg/hr). This stops the lipolysis and gluconeogenesis and allows for the conversion of ketones to bicarbonate. BS should not be allowed to fall below 250 in the first 4-5 hours of treatment. If does, change rate to 0.03 u/kg/hr. When anion gap normal, initiate SQ insulin, overlap for 1-2hr with insulin infusion. When blood sugar less than 180, can add 5-10% dextrose to IVF. 3. Potassium replacement: If initial K >6, then withhold replacement. If K< 4.5, then administer 10-20 meq/hr of K. If initial K < 3, then administer 40 meq/hr. 4. Bicarb replacement: If pH < 7.1 and/or cardiac instability present, then give bicarb 5. Phosphate replacement: Give K-phos if initial P< 1.0mg/dl. (usually high initially, due to the transcellular shift of phosphate outside the cell in the setting of acidosis and insulin deficiency)

Alcoholic Ketoacidosis Alcoholic ketoacidosis (AKA) is an acute metabolic acidosis that typically occurs in people who chronically abuse alcohol and have a recent history of binge drinking, little or no food intake, and persistent vomiting. AKA is characterized by elevated serum ketone levels, high anion gap and a normal or only slightly high plasma glucose Pathophysiology: AKA is a result of prolonged starvation with glycogen depletion, increase in counter-regulatory hormone production, dehydration, and the metabolism of ethanol itself. Due to a physical complaint (abdominal pain, vomiting), dietary intake usually ceases in these patients leading to starvation and the development of increased ketoacid production. The body's response to starvation is a decrease in insulin activity and an increase in the production of counterregulatory hormones such as glucagon, epinephrine, growth hormone and cortisol. Decrease in insulin plus an increase in the concentration of counter-regulatory hormones, primarily glucagon, result in increased lipolysis, fatty acid mobilization and transfer of fatty acids to the liver. These fatty aids are taken up by the liver and undergo fatty acid oxidation in the mitochondrion which results in the accumulation of acetyl-CoA. As mentioned previously, the liver during states of starvation is actively undergoing gluconeogenesis, diminishing the citric cycle by using up intermediates. AcetylCoA which normally enters the citric cycle for further oxidation, accumulates and is instead converted to ketoacids; -hydroxybutyrate and acetoacetate. The metabolism of ethanol leads to an accumulation in reduced nicotinamide adenine dinucleotide (NADH), which then result in 2 processes: 1) Impaired conversion of lactate to pyruvate or preferential conversion of pyruvate to lactate, both resulting in increased lactic acid levels, and 2) a shift in the hydroxybutyrate to acetoacetate equilibrium toward -hydroxybutyrate.

As a result, -hydroxybutyrate is by far, the predominant ketone in AKA . The standard nitroprusside test for de tecting ketones unfortunately only detects acetoacetate and in AKA may be falsely negative or only minimally positive, and can lead to a an underestimation of the degree of ketoacidosis. Acid base disorders in AKA These patients frequently may present with a mixed acid base disturbance: y y y y Elevated anion gap metabolic acidosis secondary to Ketoacidosis Metabolic alkalosis as a result of persistent vomiting Chronic respiratory alkalosis as a result of liver disease. Mild degree of lactic acidosis may also be present, contributing to the elevated anion gap acidosis.

History y Chronic alcoholic who goes on drinking binge y Develops pancreatitis, gastritis, which leads to abdominal pain, nausea and persistent vomiting y Symptoms leads to cessation of alcohol consumption and poor oral intake 1 to 3 days prior to presentation y Symptoms may also include that of liver disease or portal hypertension : melena, hematochezia, hematemesis, fatigue, dyspnea y Alcoholic withdrawal: tremors, seizure, hallucinations, delirium tremens Signs y Tachycardia, tachypnea, Kussmaul respiration, hypotension (possibly)

y Abdominal tenderness (particularly if pancreatitis present) y Heme-positive stools y Physical exam findings may include that of chronic liver disease: spider nevi, ascitis, hepatomegaly, caput medusa, palmar erythema, varices, jaundice, gynecomastia Laboratory findings y ABG: pH may be low high or normal depending on acid base disturbances present. PCO2 will be low, HCO3- high. Anion gap will be elevated, >16 y Serum ketones may be falsely negative, or only weakly positive. y Serum glucose may be low, normal or only slightly elevated (in contrast to DKA were glucose levels are significantly elevated) y Serum lactate may be elevated y Mg, phos, depleted low due to increased urinary excretion and poor nutrition. Phos may appear normal or high due to transcellular shift in the setting of acidosis. y Bun and Cr elevated due to prerenal axotemia y Anemia may be present due to alcohol induced bone marrow suppression, hyperspenism, or GI bleed y Hct may be falsely elevated due hemoconcentration secondary to volume loss. y Alcohol levels absent or low y LFTs may be abnormal if liver disease present. Amylase, lipase elevated if pancreatitis present Treatment y Establish ABCs. If the patient's mental status is diminished, consider administration of oxygen, thiamine, dextrose, and naloxone. Remember thiamine must be given prior to dextrose to prevent Wernicke Korsakoff. y Once the diagnosis of AKA is established, the mainstay of treatment is hydration with 5% dextrose in normal saline (D5NS.) Carbohydrate and fluid replacement reverse the pathophysiologic derangements that lead to AKA by increasing serum insulin levels and suppressing the release of glucagons and other counter -regulatory hormones. Dextrose stimulates the oxidation of NADH and aids in normalizing the NADH/NAD+ ratio. Fluids alone do not correct AKA as quickly as fluids and carbohydrates together. y Insulin contraindicated, because may lead to life threatening hypoglycemia particularly as the patients endogenous insulin levels rise with carbohydrate and fluid repletion. y Bicarbonate only given if pH < 7.1, and acidosis not responding to IVF. Starvation/ Fasting Starvation, as mentioned previously can result in ketoacidosis due to the increase in counterregulatory hormones and a decrease in insulin, a balance which promotes fatty acid oxidation, gluconeogenesis, and ketone production. However in comparison to the potentially severe ketoacidosis that develops in uncontrolled diabetes and alcoholic states, ketoacid levels do not exceed 10 meq/L with fasting. This limitation in the ketone formation may reflect the ability of ketonemia to promote insulin secretion, eventually limiting the release of free fatty acids and thus ketoacidosis Renal Tubular Acidosis Renal Tubular Acidosis (RTA) refer to a group of disorders intrinsic to renal tubules characterized by an impairment in urinary acidification which result in retention of H+ ions, reduction in plasma [HCO3-] and a hyperchloremic metabolic acidosis with a normal serum anion gap. There are 3 distinct types of RTA, each having a different pathophysiology leading to decreased acid excretion. The urinary anion gap ([Na + K] Cl- ) is usually positive in RTA due to an inability to excrete H+ . This distinguishes

RTA from the other causes of normal anion gap metabolic acidosis such as diarrhea which will have a negative urinary anion gap. Type 1 (Distal) RTA Type 1 or distal RTA is referred to as the classic RTA and is a disorder of acid excretion involving the collecting tubules. The disorder is characterized by a hypokalemic, hyperchloremic metabolic acidosis. Pathophysiology The disorder is due to defective H+ ion secretion in the distal tubule. Impairment in H+ ions secretion result in an inability to acidify the pH beyond 5.5 which retards the excretion of titratable acids (H2PO4) and NH4+ ions, thus resulting in a reduction in net acid excretion. The plasma bicarbonate is significantly reduced and may fall below 10 meq/L. The impairment in H+ ions secretion is most commonly thought to be due to a defect in the luminal H+ -ATPase pump located in the intercalating cells of the collecting tubule. The H+ -ATPase pump is primarily responsible for the hydrogen secretion in the distal nephrons. These patients tend to have urinary K+ wasting and hypokalemia. The etiology of the hypokalemia is unclear but is thought to be due to increased potassium secretion by distal tubular cells in the setting of diminished H+ ion secretion. Hypercalciuria, hyperphosphatemia, nephrolithiasis (calcium phosphate stones) and nephrocalcinosis are frequently associated with untreated type 1 RTA. The hypercalciuria is thought to be due to 1) increased calcium phosphate release from bone as a result of bone buffering of excess acid and 2) reduction in tubular calcium reabsorption secondary to chronic acidosis. The hypercalciuria, alkaline urine, and reduced excretion of citrate in the urine (which normally prevents calcium crystallization) promote the precipitation of calcium phosphate and stone formation. The hypocitraturia is thought to be due to the effects of acidosis and hypokalemia on proximal tubule reabsorption. Causes Many different conditions have been associated with type I RTA. See table below. The most common identifiable causes in adults are autoimmune disorders, such as Sjogrens syndrome . In children, RTA is most often a primary hereditary condition. Symptoms The loss of calcium salts from bones in these patients can result in failure to thrive, rickets and stunting of growth in children and osteomalacia or osteopenia in adults . Patients may otherwise be asymptomatic or may present with symptoms of severe acidosis or hypokalemia (polyuria, polydypsia, weakness and fatigue) Major causes of distal RTAIdiopathic or sporadic in children Familial Autosomal dominant Autosomal recessive Secondary (Acquired) Sjogren's Hypercalciuria Rheumatoid Arthritis , SLE Hyperglobulinemia Ifosfamide, Amphotericin , Lithium carbonate Sickle cell anemia Cirrhosis, renal transplant

Type 2 (Proximal) RTA Type 2 RTA is characterized by an impairment in proximal HCO3- reabsorption resulting in a hypokalemic hyperchloremic metabolic acidosis. Pathophysiology This condition usually appears as part of a generalized disorder of proximal tubular function known as Fanconi syndrome which also include defects in the absorption of glucose, amino acids, phosphate, uric acid, and other organic anions such as citrate. The reduction in HCO3- reabsorption leads to an increase in bicarbonate loss in the urine. Remember that a loss of a single bicarbonate ion is akin to adding one hydrogen ion to the plasma, therefore this bicarbonate loss in the urine leads to increased hydrogen ion concentration and a subsequent reduction in arterial pH. Usually about 90% of the filtered HCO3- is absorbed by the proximal tubule, the rest is absorbed by the distal nephrons. In the setting of proximal impairment of HCO3- , the distal nephrons become overwhelmed by an increase in HCO3- delivery and cannot compensate for the loss in proximal function. However as urinary HCO3- loss progresses, plasma HCO3- drops to 15-18 meq/L. This causes the level of filtered HCO3- to fall and thus there is reduced delivery of HCO3- ions to the distal nephrons. At that point, the distal nephrons are no longer overwhelmed and can regain function, leading to a reduction in bicarbonaturia and a urine which can now be acidic. This is in contrast to type 1 RTA, where urine acidification is limited to a minimum urinary pH of 5.5.

Thus type 2 RTA is a self limiting disorder in which the plasma HCO3 - concentration is usually between 14 and 20 meq/L due to the establishment of a new steady state . Urinary K+ wasting and hypokalemia are common in type 2 RTA and is due to persistent hyperaldosteronism, leading to increased K secretion by the distal nephrons. Hyperaldosteronism in these patients are related to the defect in proximal reabsorption of filtered HCO3- which in effect leads to decreased proximal NaCl reabsorption and a tendency for salt wasting. The factors responsible for the defects in proximal transport are incompletely understood. There are three features of the proximal tubules that are vital to proximal reabsorption of HCO3- : 1) the Na+H+ exchanger in the luminal membrane, 2) the Na+-K+ ATPAse pump in the basolateral membrane and 3) the enzyme carbonic anhydrase, which is located both intracellularly where it results in the generation of H+ and HCO3- , and in the lumen, where it facilitates HCO3reabsorption. It has been proposed that one or more of these factors must be impaired to account for the defect in type 2 RTA. Causes Below is a table showing some of the known causes of type II RTA. A variety of congenital and acquired disorders can cause type 2 RTA. Idiopathic RTA and cystinosis are most common in children; carbonic anhydrase inhibitors and multiple myeloma are most often responsible in adults. Complications As in type 1 RTA, bone disease also occurs due to an increase in bone buffering of excess acid and the release of calcium salts from bone. Also contributing to this problem is acquired vitamin D deficiency, since the proximal tubule is a major site of form ation of calcitriol.

Defects in proximal transport may also result in phosphate wasting and hypophosphatemia leading to decreased deposition of mineral in bone. Rickets in children and osteomalacia or osteopenia in adults are relatively common in type 2 RTA, occurring in up to 20% of cases. In contrast to type 1 RTA, nephrocalcinosis and nephrolithiasis does not occur , and this is due to normal levels of urinary citrate in this condition (in contrast to type 2) and the ability to acidify the urine which increases the solubility of calcium phosphate. Major Causes of type 2 RTA Idiopathic or sporadic in children Hereditary A. Cystinosis B. Galactosemia C. Tyrosinemia D. Glycogen storage disease, type 1 E. Wilson's disease Acquired disorders A. Multiple Myeloma B. Hypocalcemia and vitamin D deficiency C. Drugs and Toxins: (Acetazolamide or other carbonic anhydrase inhibitor, Ifosfamide, Streptozocin, Lead, Cad mium, Mercury, outdated tetracycline) D. Amyloidosis E. Renal transplant rejection

Type 4 RTA Type IV RTA is the only type characterized by a hyperkalemic, hyperchloremic acidosis. The defect is thought to be Aldosterone deficiency or resistance. Pathophysiology Aldosterone deficiency or resistance impairs the secretion of hydrogen and potassium ion resulting in acidosis and hyperkalemia. The hyperkalemia is usually very prominent in this condition and has an important role in metabolic acidosis by impairing ammonium production and acid excretion in the urine. The hyperkalemia in this setting impairs NH4+ production in the proximal tubule by inducing a state of intracellular alkalosis within the tubular cell. This occurs due to the transcellular exchange of potassium for hydrogen resulting in the exit of hydrogen ion from the cell. The development of intracellular alkalosis reduces NH4+ secretion by the proximal tubular, which in combination with decreased hydrogen secretion distally, result in decreased ammonium excretion and decreased net acid excretion. Reversing this process by correcting the hyperkalemia often leads to increased NH4+ excretion and correction of the metabolic acidosis The metabolic acidosis seen with hypoaldosteronism is generally mild, with the plasma [HCO3-] usually above 15 meq/L. Despite the impairment in distal H+ secretion, the urine pH in this disorder is generally but not always below 5.3, in contrast to type 1 RTA. The ability to acidify the urine in this condition is due to the inadequate amount of NH3 available for buffering of protons. Even if only a few protons are secreted distally, urinary pH will fall in the absence of buffers. This is in contrast to type 1 RTA where distal H+ secretion is impaired and any protons secreted will be buffered by available NH3 , thus maintaining an alkaline urine.

Causes Type 4 RTA due to aldosterone deficiency has multiple etiologies. Hyporeninemic hypoaldosteronism is the most common cause and is usually asscoiated with mild to moderate renal insufficency. It is most commonly found in diabetes nephropathy and chronic interstitial nephritis . NSAIDS, ACE inhibitors, trimeto prim and heparin can all reduce aldosterone production and produce a type 4 RTA. Drug-induced type 4 RTA is usually seen in patients with pre-existing renal insufficiency. Patients with tubular resistance to aldosterone will present very similarly to hyporeninemic hypoaldosteronism. It is thought to be due to a tubulointerstial process that damages the distal tubule causing retention of hydrogen and potassium ions despite adequate aldosterone. BPH and sickle cell disease are the most common causes. Spironolactone has also been known to cause an aldosterone resistant state. Symptoms Type IV RTA is usually asymptomatic with only mild acidosis, but cardiac arrhythmias or paralysis may develop if hyperkalemia is extreme.

Diagnosis of RTA Type I RTA The findings of hypokalemic, normal anion gap metabolic acidosis with an inappropriately high urine pH (>5.5) and postive urine anion gap confirm the diagnosis. In patients with a normal plasma bicarbonate concentration, the failure to lower urinary pH to less than 5.5 after an acute acid challenge with NH4Cl defines the syndrome of incomplete classic distal RTA Type II RTA The diagnosis of type 2 RTA is made by measurement of the urine pH and fractional bicarbonate excretion during a bicarbonate infusion.The plasma bicarbonate concentration is raised toward normal (18-20 meq/L) with an intravenous infusion of sodium bicarbonate at a rate of 0.5 to 1.0 meq/kg/hour. The urine pH , even if initially acidic, will rise rapidly once the reabsorptive threshold for bicarbonate is exceeded. As a result, the urine pH will be above 7.5 and the fractional excretion of bicarbonate will exceed 15% . Type IV RTA The findings of hyperkalemic, normal anion gap metabolic acidosis with an appropriately low urine pH ( 5.5 Type 2 RTA Diminished proximal HCO3reabsorption Yes Positive Variable, > 5.5 if given an alkali load Low > 15 Usually 14- 20 meq/L Normal Normal No Yes Type 4 RTA Aldosterone deficiency or resistance yes Positive < 5.5 Yes Negative 5 to 6 GI Bicarbonate loss

Normal Anion-gap acidosis Urine anion gap Minimum urine ph

Serum K % filtered bicarbonate excreted Plasma [HCO3-], untreated Daily acid excretion GFR Stones/nephrocalcinosis Fanconi syndrome Treatment of RTA Type 1 RTA

Low < 10 May be below 10 meq/L Low Normal Yes No

High < 10 Usually above 15 meq/L Low Low No No

Low < 10

High NA No No

Treatment of acidosis is generally indicated in type 1 RTA to allow normal growth to occur in children, to minimize stone formation, nephrocalcinosis, and possible osteopenia due to calcium loss from bone, and to diminish inappropriate urinary K losses. Alkali supplement is the standard therapy. Enough alkali is usually prescibed to titrate the fraction of daily acid load that is not excreted. In adults, this is usually 1-2 meq/kg/day. Patients are generally treated with NaHCO3 or sodium citrate. Many patients do not need potassium replacement since correction of acidemia leads to marked improvement in potassium wasting. However patients with significant hypokalemia, calcium stones, or nephrocalcinosis require potassium and are treated with potassium citrate or Polycitra (potassium citrate plus sodium citrate). Type 2 RTA Alkali therapy is required for normal growth in children and to prevent or treat osteopenia/osteomalacia in adults. Reversal of acidemia is difficult since the exogenous alkali is rapidly excreted in the urine. As a result, much higher doses of alkali are required in comparison to type 1 and 4 RTA. About 10-15 meq/kg/day of alkali is typically required to stay ahead of urinary excretion.

The preferred therapy is potassium citrate which also helps with potassium losses in this disorder. Thiazides are also sometimes used with low salt diet to reduce the amount of alkali required. Thiazides induced volume contraction can be used to enhance proximal HCO3- reabsorption leading to improvement in bicarbonaturia and renal acidification. If hypophosphatemia is present, vitamin D and phosphate supplement is also required. Type 4 RTA Therapy is aimed mainly at reducing serum potassium, as acidosis will usually improve once the hyperkalemic block of ammonium production is removed. All patients should be placed on a low potassium diet. Any drugs that suppresses aldosterone production